KR101572134B1 - Anti-slip pad usable in various conditions with easy usability - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a non-slip pad and a pattern structure thereof that can be easily mounted on and detached from a shoe.
According to the present invention, by manufacturing the non-slip pad in this way, it can be efficiently used in various environments. Especially, it is more stable and effective than existing anti-slip pads. In addition, it can be manufactured as one body, it can be manufactured to be separated type according to the situation, and can be easily adjusted in length and can be detached (banded) in a band form. It is easy to wear and does not peel off during use because it uses an auxiliary band that connects to the back of the ankle. Depending on the user's choice, two sliding pads can be used (top pads to prevent water slip and slip and bottom pads to prevent slippage on ice).

Description

[0001] The present invention relates to an anti-slip pad for an anti-slip pad,

The present invention relates to a non-slip pad which can be worn on the outside of a shoe. Pedestrians are slippery and prone to hurt when ice is frozen or snow is piled up. In order to prevent this, Eisen is used for mountain climbing but it is difficult to use in various environments such as the city center due to its sharp metal and high height. Currently, there are many pads to prevent slippage, but they are inconvenient to use and can not effectively prevent slippage. Also, if you go to a place where snow or ice is freezing and you go to a place where it is not frozen, the slip-resistant pad may make it difficult to walk, and it may cause a strain on your ankle. Also, it can not cope with rain, oil and other slippery situations.

Typical falls occur in winter. In particular, the slip caused by slippage in winter occurs more than 60% in residential facilities and their surroundings. The injury of the elderly due to such a fall is fatal, and it is an accident to be careful not to fall over by winter slip to all people such as children and youth.

By using anti-slip pads, many fall accidents can be prevented. Various types of slip-resistant shoes, life-size ezines, and anti-slip pads are on sale now. In the case of a non-slip pad attached to the lower part of the shoe, there is a non-slip pad in various ways such as ceramic sprayed to improve frictional force or rubber having a high friction coefficient. In the case of the non-slip pad attached to the shoe, the manufacture is easy and the effect is good. However, since the pads must be pasted using an adhesive, marks on the shoes are likely to remain and fall off well. It also slips well on slippery grounds such as on ice.

Second, in the case of a product such as a conventional Eisen which is prevented from slipping by wearing in a shoe, it has a disadvantage that it is difficult to use in various environments because of its high pin shape.

Third, the shoe is made of rubber doped with ceramic to enhance friction. This kind of shoe has a feeling of good feeling because it does not require additional work unlike the previous non-slip shoe, but has a problem that the durability of the shoe is lowered because the slip efficiency is low and the life of the rubber is lowered compared with other general shoes.

KR 20-0278203 Y1 KR 10-0976276 B1 KR 10-0969073 B1 KR 10-2003-0056182 A KR 10-2002-0009641 A KR 20-0292253 Y1

Disclosure of Invention Technical Problem [8] The present invention has been made to solve the above problems, and it is possible to prevent slippage in a situation where snow is piled up on a pad attached to a lower portion of a shoe. However, in extreme situations such as above ice, hard solid snow, etc., it does not prevent slipping efficiently. The same applies to the case where the shoe itself is made of a material capable of improving friction to prevent slipping. Products that use protruding pin shapes such as Eisen can surely prevent slippage on ice. However, since the slippage prevention pin is high when the snow is low, the feeling of wearing is low and the user is uncomfortable. These products also have problems in daily use. In addition, it has a high coefficient of friction through ceramic-doped rubber, foam rubber and pattern molding which is currently being actively developed to prevent the occurrence of water film phenomenon, so that a general slippery field (for example, a workshop with oil on the floor, , A bathroom, a kitchen, etc.). However, in winter with snow and ice, its effect diminishes.

Therefore, there is a need for a multi-functional non-slip pad that can be used in various environments. There is also a need for a non-slip pad that maximizes user comfort and improves slip efficiency in a variety of environments. In addition to winter, there is a need for an easy-to-use non-slip pad in a variety of slippery environments (typically slippery toilets, bathrooms, galleys, workshops, etc.). It should be easy to wear, easy to remove, and should not fall out after wearing once.

According to an aspect of the present invention, there is provided a non-slip pad comprising: a non-slip pattern formed of a plurality of protruding polygonal or circular shapes; A metal pattern provided inside each of the polygonal shapes or circular shapes and configured in a plurality of pyramid shapes of metal; And a pad (hereinafter, referred to as a "first pad") having the metal pattern on the inside of each polygonal or circular shape of the non-slip pattern, the plurality of pyramids The shape includes a central pyramid shape formed at the inner center of the non-slip pattern; A side pyramid shape formed on an outer side surface of each of two longitudinal sides of the central pyramid-shaped bottom surface and an outer side surface of each of the two transverse sides; And a corner pyramid shape formed so that one diagonal line of the bottom surface is positioned on each line connecting the pyramid shapes of the side portions adjacent to each other at the shortest distance in the side pyramid shape, and the corner pyramid shape is formed by the central pyramid shape and the side pyramid shape And a space is formed between the non-skid pattern and the metal pattern so that an eye column can be formed to prevent slippage by pushing or pulling the eye of the floor as the user moves.

The shapes of the plurality of pyramids may be configured such that they do not overlap each other in their arrangement.

The shape of the plurality of pyramids may be configured such that there is no enclosed area such that snow and ice are not accumulated.

Each of the pyramid shapes may be arranged in a form in which pyramid shapes and empty spaces are alternately arranged in each row and each column in which the respective pyramid shapes are arranged so as to strongly adhere to snow or ice to prevent slippage.
Each of the pyramid shapes may be formed in such a manner that the pyramid shape and the empty space are alternately arranged, and a gap that allows the eyes to escape in the diagonal direction may be formed.

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The non-slip pattern is preferably made of a foam rubber material.

It is preferable that the foamed rubber material is distributed with a ceramic component.

The non-slip pattern and the metal pattern are connected to each other through a hole for connecting the non-slip pattern and the metal pattern, And can be fixed.

According to another aspect of the present invention, a non-slip pad detachable to a shoe comprises: the non-slip pad; And a pad mounting band which is composed of a bending material and is equipped with the non-slip pad, and is detachably attached to the shoe.

The pad mounting band may further include a pad (hereinafter, referred to as a 'second pad') having a protruding pattern for preventing slipping as a bending material and having no metal pattern.

The non-slip pad detachable to the shoe may further include an auxiliary band attached to the pad mounting band and connected to the back of the ankle so as to prevent the slip-resistant pad from slipping in front of the shoe during use.

The non-slip pad detachable to the shoe is mounted on the shoe so that the pad selected from the first pad and the second pad comes into contact with the road surface according to the state of the road surface, The pads contacting the road surface of the first pads and the second pads may be changed by rotating the pads in a state where the pads are mounted on shoes.

It is preferable that the pad mounting band has a fastening portion for fastening both ends, and the length can be adjusted by the fastening portion.

According to the present invention, by manufacturing the non-slip pad in this way, it can be efficiently used in various environments. Especially, it is more stable and effective than existing anti-slip pads. In addition, it can be manufactured as one body, it can be manufactured to be separated type according to the situation, and can be easily adjusted in length and can be detached (banded) in a band form. It is easy to wear and does not peel off during use because it uses an auxiliary band that connects to the back of the ankle. Depending on the user's choice, two sliding pads can be used (top pads to prevent water slip and slip and bottom pads to prevent slippage on ice).

The pyramid-shaped metal pattern can be firmly adhered to the eyes and ice by the pyramid shape to improve the frictional force and prevent the slip under extreme circumstances. The diagonal line of the pyramid shape can escape snow that can clump in the center.

By using the anti-slip pad according to the present invention, a sliding state in various environments (1) a state in which snow starts to fall and a soft snow is piled up (2) a state in which the eyes are hardened (3) the ice is frozen (4) snow is piled up on the ice (5) the snow starts to melt or the snow is falling while melting. It can be used in all situations depending on the pad (upper pad, lower pad) used, and it can also be used in various slippery environments (generally slippery toilet, bath, cooking room, workshop, etc.).

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a schematic view showing a non-slip pad (upper pad) without a metal pattern which is one of the slip prevention pads proposed in the present invention; Fig.
Fig. 2 is a schematic view showing a non-slip pad (lower pad) to which a hexagonal metal pattern is bonded. Fig.
3 is a schematic view of a non-slip pin shape based on a pyramid shape for efficient slip prevention according to the present invention.
4 is a schematic view showing a method of working a non-slip fin according to the present invention.
FIG. 5 is a schematic view showing a product in which the anti-slip metal pattern of FIG. 3 is connected to a non-slip pad (lower pad) to which the metal pattern of FIG. 2 is bonded.
6 is a schematic view showing an integrated product of an upper pad and a lower pad (Embodiment 1).
7 is a schematic view showing an integrated product of Example 1 and an auxiliary band (Example 2) attachable to an integrated product.
FIG. 8 is a schematic view showing a sub band length adjusting method of FIG. 7 and a connecting method of the embodiment 1. FIG.
9 is a schematic view showing a case in which Embodiment 2 in which an auxiliary band is added to the integral product of Embodiment 1 is worn.
10 is a schematic view of a third embodiment using a length adjusting and fixing method when the upper pad and the lower pad are not integrally connected.
11 is a schematic view showing Embodiment 4 in which an auxiliary band is attached to Embodiment 3. Fig.
12 is a schematic view showing an anti-slip pad having an elliptical shape applicable to Embodiments 1 to 4. Fig.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to this, terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary terms, and the inventor should appropriately interpret the concepts of the terms appropriately It should be interpreted in accordance with the meaning and concept consistent with the technical idea of the present invention based on the principle that it can be defined. Therefore, the embodiments described in this specification and the configurations shown in the drawings are merely the most preferred embodiments of the present invention and do not represent all the technical ideas of the present invention. Therefore, It is to be understood that equivalents and modifications are possible.

The non-slip pad according to the present invention may include the two pads of FIGS. 1 and 2.

FIG. 1 is a schematic view showing a non-slip pad (upper pad) 11 having no metal pattern which is one of the non-slip pads proposed in the present invention.

In the case of the upper pad 11, it is composed of an upper pad pattern 12 for preventing water film development and slipping, and has a high coefficient of friction and high strength. In the case of the upper pad 11, a foam rubber can be used to prevent a water film phenomenon. In addition, a rubber containing ceramics can be used for high water repellency, no water film development, high durability, and improved friction coefficient. By using such a material, the elasticity can be maintained even when the weather is cold. Also, unlike the conventional pattern shape, the upper pad pattern 12 for preventing various sliding phenomena and slipping can be used as shown in FIG. 1 for improving the frictional force and the grounding force.

The upper pad pattern 12 for preventing the water film phenomenon and slipping of Fig. 1 is formed of a regular hexagonal repeating shape. A flow path can be formed in the empty space by dividing by a square having the same area. In addition to hexagons, various shapes such as square, octagonal, etc. can be used. By using such a repetitive shape, it is possible to prevent the water film phenomenon through the flow path formed in the pattern, and to smooth out the medium which can cause slippage of water, ice oil, snow and the like. In addition, since the direction of the contact is not constant and varies along the shape, it is possible to improve the friction force and prevent slippage in various environments. The anti-slip top pattern 13 can be made of rubber having stronger strength and friction coefficient than other top pads. By providing such a slip prevention pattern on the outside, it is possible to improve the friction coefficient of the entire upper pad and to prevent slippage in various environments. This provides a higher anti-slip effect compared to other products because it prevents water filming and improves friction on a large area.

2 is a schematic view of a non-slip pad (lower pad) 21 to which a metal pattern according to the present invention is bonded.

The slip prevention pad (lower pad) 21 to which the metal pattern is bonded includes a metal pattern bonding region 22 and a lower pad non-slip pattern 23, a lower pad contact agglomeration prevention hexagonal pattern 24, ).

An anti-slip metal pattern 32 having a pyramid as a basic shape is placed between the polygonal rubber patterns 22. The hexagonal pattern (24), which prevents the bunching of the lower pad, has a space inside each pattern, so that a small eye column is formed in the space between the same as the snow tires, and by pushing or pulling the eyes located therebetween (using shear force) Prevent slipping. It also prevents snow and ice from clumping. In addition, it drains smoothly and removes the water film phenomenon on the ice. The non-slip pad 21 to which the metal pattern is bonded is made of foam rubber, distributes the ceramic to improve the frictional force of the material itself, and maintains elasticity even when the weather is cold.

A non-slip metal pattern 31 having a basic shape of a pyramid according to the present invention is connected to the metal pattern bonding region 22, and the metal pattern can be fixed to the upper pad through the metal pattern connection hole 25. [ In the case of the lower pad non-slip pattern 23, like the upper pad non-slip pattern 13, it can be made of rubber having stronger strength and friction coefficient than other pad materials. When such a slip prevention pattern is located outside, the friction coefficient of the non-slip pad is improved.

The hexagonal pattern 24 for preventing aggregation of the lower pad forms a space between the hexagonal pattern and the metal pattern. This creates a small snow pillar in the space between the patterns as snow tires and prevents slippage by pushing or pulling the snow on the bottom (using shear force) as the user moves. In addition, snow and ice are prevented from clumping and drainage is made smooth so that the water film phenomenon does not occur. The hexagonal pattern 24 thus formed does not have to be a hexagonal pattern. Both rectangular and circular patterns are possible. In terms of space efficiency, using a hexagon is more efficient than using a simple shape. When the direction of the non-slip pad user is taken into consideration, the diagonal slip can not be prevented in the case of the square pad, but it is possible to prevent the slip in all six directions in the case of the hex pad. Therefore, it is most efficient to use a hexagonal pattern.

FIG. 3 is a schematic view showing a shape of a non-slip pin based on a pyramid shape for efficient slip prevention according to the present invention.

There is no overlapping of pyramid parts and there is a slip-resistant metal pattern which is composed of center part, side part and corner part, and there is no enclosed area and snow and ice do not accumulate. This will be described in detail below.

The pyramid-shaped anti-slip pattern can be easily adhered to ice and snow and can be stuck to prevent slipping on snow and ice. In particular, each pyramid shape is arranged in such a manner that pyramid shapes and empty spaces are alternately arranged in each row and each column in which each pyramid shape is arranged, as shown in Fig. 3, so that the pyramid shape is strongly adhered to the eyes and ice Can be prevented. There is a gap in the diagonal line, and through this gap, the snow that can clump to the center can escape.

The pyramid pattern can be composed of a total of 9 patterns, and the arrangement of the patterns is shown in FIG. The arrangement of the pattern can be confirmed through the front view 32 of the anti-slip metal pattern, which is a right side view of FIG. The pattern consists of a side pyramid shape 34, a corner pyramid shape 35, and a central pyramid shape 36. The shape of the central pyramid is a quadrangular pyramid. In the case of the side and the corner, the size of the pyramid is determined by the size of the pyramid of the central part. The side pyramid shape may not be circumscribed or circumscribed as shown in Fig. The height of the pyramid is the same as the height of the central pyramid 36 and the side pyramid 34. In the case of the corner pyramid 35, the height is lower than the side portion. When the ice and snow are in contact with the metal pyramid shape, the center pyramid shape 36 and the side pyramid shape 34 come into contact first. And the corner pyramid shape 35 comes into contact.

Pyramid shapes come into contact with snow and ice, causing the snow and ice to crumble and become deformed. At this time, the remaining snow and ice on the snow and ice may clump together in the metal pattern. The metal pattern 31 using the pyramid shape according to the present invention moves around the pyramid shape without snow and ice being gathered. And then slipped out along the side pyramid 34 and the corner pyramid 35. As described above, the snow and ice outside the pyramid region bring about a slip prevention effect and an anti-snow accumulation effect by the anti-snow hexagonal pattern 24.

A side view (33) of the anti-slip metal pattern is the same as the lower right end of Fig. As can be seen from the side, it shows the same cross section. Such having the same cross section is for convenience of processing. And the angle of the side pyramid 34 is higher than that of the central pyramid 36, so that the pyramid pattern can easily be stuck in snow and ice. Metal pattern materials are available for both stainless steel and heat-treated carbon steels with high strength and no rust.

Fig. 4 is a schematic view showing a method of machining a non-slip fin according to the present invention.

First, a plate material 41 on which a pyramid pattern is formed is manufactured by CNC machining. This is because the pyramid pattern has the same cross section as seen from the end faces 42 and 43 of the formed plate material, so that it can be easily manufactured through CNC machining. It is possible to manufacture the plate member 41 having the pyramid pattern formed by machining the mountain shape in each direction and then removing the remaining portion. The slip prevention metal pattern 31 having the pyramid as a basic shape can be manufactured by cutting the plate material 41 having the pyramid pattern formed thereon into a hexagon as shown in FIG. In addition to cutting, it can be manufactured by forging, casting, etc., and can be manufactured by a similar method.

FIG. 5 is a schematic view showing a product in which the anti-slip metal pattern of FIG. 3 is connected to a non-slip pad (lower pad) to which the metal pattern of FIG. 2 is bonded.

The overall shape is a shape in which a non-slip metal pattern 31 having a pyramid as a basic shape is bonded to the metal pattern bonding region 22 of Fig. The non-slip pattern according to this embodiment includes a total of twelve metal patterns. This is not a fixed number, but can be further increased to increase slip prevention efficiency. The connecting method connects the metal pattern 31 and the non-slip pad connecting device 52 of the pyramid pattern through the metal pattern connecting hole 25 simply. At this time, the anti-slip pad connecting shaft 51 of the pyramid pattern can be used as the connecting shaft. The non-slip pad connecting device 52 of the pyramid pattern may be a bolt, or various methods such as mechanical bonding such as an adhesive and a rivet may be used. Since the surface of the connecting device 52 is in contact with shoes, knurling can be performed to improve frictional force.

≪ Example 1 >

6 is a schematic view showing Embodiment 1 which is one embodiment of a non-slip pad according to the present invention.

6, when the non-slip pads are integrally formed, all of the components other than the metal pads can be formed by injection molding at one time. Then, the anti-slip metal pattern 31 having the pyramid as a basic shape may be connected to the lower pad. In such a case, since there is no way to adjust the size, even if the product is manufactured by dividing into three pieces for shoe size 230 to 250 mm, 250 to 270 mm, and 270 mm to 290 mm, the circumference may vary depending on the user's shoe. The mounting method is to stretch the band and pull it at the same time to move it over the foot. The surface located toward the bottom of the feet performs the anti-slip function. In the case of the left drawing, since the upper pad 11 is directed toward the bottom, general slip prevention is possible. In the case of the right drawing, since the lower pad 21 is directed toward the bottom, it is possible to prevent slippage in extreme situations such as on snow and ice. Thus, each of the anti-slip pads plays a different role, and the user can freely adjust the use surface according to the purpose. That is, the rubber pads composed of both sides can determine the surface on the shoe or the shoe bottom depending on the use environment.

The non-slip pad can be made by injection molding rubber. In this case, general rubber or the like can be used, and a porous rubber can be used to prevent formation of oil film and water film. Of course, it is possible to use rubber with improved friction because it contains ceramics and the like. The metal pattern of the lower pad can be affixed to the lower pad through a mechanical connection such as a rivet through a pin shape. It can also be inserted using the elasticity of the rubber, and metal and rubber can be simultaneously injected during the manufacturing process.

≪ Example 2 >

7 is a schematic view showing an integrated product of Example 1 and a secondary band attachable to the integrated product (Example 2). If you are using regular shoes, you can only use the non-slip pads and you may lose the non-slip pads in front of the shoes even if you adjust the length. In this case, when the auxiliary band 71 is attached to the back of the ankle, the non-slip pad can be used without being detached. By using the auxiliary band 71, it is possible to improve the wearing feeling in use of the upper pad and the lower pad and to prevent the upper pad and the lower pad from falling out of the shoe. As shown in the lower part of FIG. 7, the auxiliary band is detachable and can be used separately. The auxiliary band can be used when moving a short distance, and the auxiliary band can be used when moving a long distance. It can also be used by user as desired.

FIG. 8 is a schematic view showing a method of adjusting the length of the auxiliary band 71 of FIG. 7 and a method of connecting the integrated product (Embodiment 1).

The auxiliary band must be adjustable in length and able to be mounted on a non-slip pad. As shown in FIG. 8, it can be fixed on the anti-slip pad without attaching a device for mounting the auxiliary band. The auxiliary band and non-slip pad connection pin 72 may be made of metal to allow elastic deformation and then to be fitted to the band as shown in FIG. 8 when the force is exerted. In the case of once fitting, the connecting pin 72 is not removed unless force is applied again. Also, when the anti-slip pads are of the same cross-section, the connecting pin 72 can move in the pad. In order to prevent this, the shape of the connection pin 72 may be changed to a position as shown in the lower right of FIG.

The length of the auxiliary band can be adjusted. In the case of adjusting the length, a pin structure 73 for adjusting the length of the auxiliary band, which can be adjusted and fixed by friction and pressing force three times, can be used as shown in FIG. One side of the auxiliary band is connected to the pin structure 73 and the connection pin 72 for adjusting the length, and the connection pin 72 for connection can be located on one side.

9 is a schematic view showing a case in which Embodiment 2 in which an auxiliary band is added to the integral product of Embodiment 1 is worn.

Referring to FIG. 9, the upper pad is directed upward, and the lower pad is used to prevent slippage on snow and ice.

In addition, the non-slip pad detachable to the shoe can be mounted on the shoe so that the selected pad of the upper pad or the lower pad comes into contact with the road surface depending on the state of the road surface, The pads contacting the road surface of the upper and lower pads may be changed by rotating the pads in a state in which they are mounted on the shoe.

≪ Example 3 >

10 is a schematic view of a third embodiment using a length adjusting and fixing method when the upper pad and the lower pad are not integrally connected.

It may be difficult to manufacture the upper pad and the lower pad as a complete circular or integral type according to the manufacturing method. In this case, upper and lower pads can be fabricated in a plane. It should also be able to connect one side. In the third embodiment, a buckle capable of adjusting and fixing the length is used so that the length can be adjusted and fixed. The length adjustment can use the same structure as the pin structure (73) for adjusting the auxiliary band and the auxiliary band length. In case of fixing, buckle can be used. The buckle is composed of a buckle 102 to be fitted and a buckle 103 to be inserted. The pin structure 73 for adjusting the length can be connected to one of the fitting side and the fitting side. In this case, adjust the length slightly smaller than the circumference of the instep, then connect the buckle, the slip pad will not come off the shoes. Even when the pad is turned, the buckle can be removed and fixed easily. It is easy to use because it is easy to adjust the length even if the user changes or the size of the shoes changes.

<Example 4>

11 is a schematic view showing Embodiment 4 in which a subsidiary band is attached to Embodiment 3. Fig.

This is because the auxiliary band 71 is attached to the third embodiment, and length adjustment is possible on both sides (non-slip pad, auxiliary band). And the auxiliary band is constructed in the same manner as in the second embodiment. One of which is a connecting pin 72 and the other of which is composed of a pin structure 73 for controlling the length and a connecting pin 72. Also in the case of the non-slip pad, the pad shape may be slightly modified as in the second embodiment, and the auxiliary pad may be in one position. The buckle is the same as in the third embodiment.

&Lt; Example 5 >

12 is a schematic view showing an anti-slip pad having an elliptical shape applicable to the first to fourth embodiments.

Owing to the elliptical shape, the slip prevention efficiency can be further improved by dispersing the force acting on the pad in accordance with the traveling direction of the user, and a good aesthetic effect can be obtained.

11: Non-slip pad without metal pattern (upper pad)
12: Top pad pattern to prevent water film phenomenon and slip
21: a non-slip pad (lower pad) to which a metal pattern is bonded;
22: metal pattern bonding region
23: Lower pad non-slip pattern
24: Lower Pad Hex Pattern
25: metal pattern connection hole
31: Non-slip metal pattern having a pyramid as a basic shape
32: Non-slip metal pattern front view
33: Side view of anti-slip metal pattern
34: side pyramid shape
35: Corner pyramid shape
36: Center pyramid shape
41: Plate with pyramid pattern formed
42: Cross-section of a plate with a pyramid pattern formed
43: section 2 of the plate in which the pyramid pattern is formed
44: Cutting method
51: Non-slip pad connection axis of pyramid pattern
52: Non-slip pad connection of pyramid pattern
71: Auxiliary band for stable fixing
72: Auxiliary band and non-slip pad connection pin
73: Pin structure for adjusting the auxiliary band length
81: Shoes
101: Adjustable and fastenable buckle
102: Side to be fitted buckle
103: Insertion buckle

Claims (15)

As a non-slip pad,
A non-slip pattern formed of a plurality of protruded polygonal shapes or circular shapes;
A metal pattern provided inside each of the polygonal shapes or circular shapes and configured in a plurality of pyramid shapes of metal; And
(Hereinafter, referred to as &quot; first pad &quot;) having the metal pattern inside each polygonal or circular shape of the non-slip pattern,
Lt; / RTI &gt;
Wherein the plurality of pyramidal shapes comprise:
A central pyramid shape formed at the inner center of the non-slip pattern;
A side pyramid shape formed on an outer side surface of each of two longitudinal sides of the central pyramid-shaped bottom surface and an outer side surface of each of the two transverse sides; And
In the side pyramid shape, a corner pyramid shape formed so that one diagonal line of the bottom surface is located on each line connecting the side pyramid shapes adjacent to each other at the shortest distance
Lt; / RTI &gt;
The corner pyramid shape,
The center portion pyramid shape and the side portion pyramid shape,
A space is formed between the non-slip pattern and the metal pattern so as to prevent the slip by pushing or pulling the eye of the floor as the user moves
Wherein the anti-slip pad comprises: The method according to claim 1,
The shape of the plurality of pyramids,
The arrangement being such that there are no overlapping parts in the arrangement
Wherein the anti-slip pad comprises: The method according to claim 1,
The shape of the plurality of pyramids,
It is constructed so that there is no enclosed area so that snow and ice do not accumulate.
Wherein the anti-slip pad comprises: delete The method according to claim 1,
Each of the pyramidal shapes includes
In which pyramid shapes and empty spaces are alternately arranged in each row and each column in which the respective pyramid shapes are arranged so as to strongly adhere to snow or ice to prevent slippage
Wherein the anti-slip pad comprises: The method of claim 5,
Each of the pyramidal shapes includes
The pyramid shape and the empty space are arranged in an alternate arrangement form, and a gap is formed so that the eye can escape in the diagonal direction
Wherein the anti-slip pad comprises: The method according to claim 1,
The anti-
Being foam rubber material
Wherein the anti-slip pad comprises: The method of claim 7,
In the foamable rubber material,
Ceramic components distributed
Wherein the anti-slip pad comprises: delete The method according to claim 1,
Inside the polygonal or circular shape,
And a hole for connecting the non-slip pattern and the metal pattern,
Wherein the non-slip pattern and the metal pattern are attached and fixed by connecting the non-slip pattern and the metal pattern connecting device through the hole
Wherein the anti-slip pad comprises: As a non-slip pad for removable shoes,
The anti-slip pad of claim 1; And
A pad mounting band which is made of a bending material and is equipped with the anti-slip pad of claim 1,
Including a removable, non-slip pad on the shoe. The method of claim 11,
In the pad mounting band,
(Hereinafter referred to as &quot; second pad &quot;) having a protruding pattern for preventing slippage as a bending material,
Wherein the shoe is detachably attached to the shoe. The method of claim 11,
A pad mounting band,
By connecting to the back of the ankle, the auxiliary band prevents the slip-resistant pad from slipping out in front of the shoe during use
Wherein the shoe is detachable from the shoe. The method of claim 12,
The non-slip pad detachable to the shoe includes:
When the pad is mounted on a shoe, the selected one of the first pad and the second pad is mounted so as to be in contact with the road surface according to the state of the road surface,
The pads contacting with the road surface of the first pads and the second pads can be changed by rotating the pads in a state where the pads are mounted on the shoe according to the state of the road surface
Which is characterized by a removable, non-slip pad on the shoe. The method of claim 11,
The pad mounting band
And a fastening portion for fastening both ends,
The length of which can be adjusted by the fastening portion
Which is characterized by a removable, non-slip pad on the shoe.

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